Purificación de aire mediante oxidación fotocatalítica de gases contaminantes NOₓ: estudio de los fotocatalizadores TiO₂ y ZnO

Los óxidos de nitrógeno (NOx) son gases contaminantes que afectan al medio ambiente al ser responsables de la formación de smog fotoquímico, lluvia ácida, ozono troposférico, reducción de la capa de ozono, además de participar en el efecto invernadero en la forma de N2O. Adicionalmente, la exposición a estos gases provoca daños a la salud de los seres humanos. Una propuesta tecnológica para abordar esta problemática ambiental es su eliminación mediante un proceso fotooxidativo, lo cual requiere del empleo de óxidos semiconductores con alta actividad fotocatalítica. En el presente trabajo de investigación se valoró el alcance de la tecnología de fotocatálisis heterogénea para la purificación de aire por eliminación de gases tipo NOx. Para este propósito, en una primera parte del trabajo se construyó un reactor fotocatalítico de acuerdo a la norma internacional ISO 22197-1 con el fin de realizar las pruebas fotocatalíticas en condiciones estándar a las establecidas por la regulación internacional y dar así consistencia a los resultados obtenidos. La segunda parte del trabajo consistió en la síntesis y caracterización de los óxidos semiconductores TiO2 y ZnO por el método sol-gel para lo cual en cada caso se aplicó un diseño de experimentos con el fin de encontrar las condiciones experimentales que permitieran la obtención del mejor fotocatalizador de cada sistema en base a sus propiedades fisicoquímicas. La actividad fotocatalítica de las muestras de TiO2 y ZnO se determinó en la reacción de fotooxidación de óxido nítrico (NO) en aire bajo radiación UV. Los mejores fotocatalizadores fueron seleccionados para pruebas de desempeño variando las condiciones experimentales de la reacción fotocatalítica como el caudal volumétrico que entró al reactor, la irradiancia y la cantidad de humedad presente en el medio de reacción, evaluando además el efecto de diversas variables experimentales de la reacción fotocatalítica en sus respectivos valores. Asimismo, el seguimiento de los productos de reacción confirmó la presencia iones nitrato (NO3-) como producto mayoritario de la fotooxidación de NO, lo que dota al proceso de eliminación de NO de un carácter sustentable. En una tercera parte del trabajo se probó la actividad fotocatalítica del fotocatalizador TiO2 cuando fue incorporado en un prototipo de material de construcción. El desempeño fue probado bajo condiciones simuladas y reales de exposición a la intemperie. Los resultados obtenidos indicaron la potencial aplicación de los materiales para el desarrollo comercial de productos fotocatalíticos. En la parte final del trabajo se presentan resultados obtenidos con óxidos semiconductores alternos a los convencionales como Bi2Mo3O12 y TiO2/WO3 cuyo principal propósito fue el de desarrollar fotocatalizadores cuya activación fuera mediante absorción en la porción visible del espectro solar.

Evaluación de las características de liberación de isoniazida a partir de un biomaterial cerámico

La tuberculosis es un serio problema de salud pública, esta enfermedad representa la segunda causa de muerte ocasionada por un agente infeccioso. Una de las razones de la elevada tasa de morbi-mortalidad es la multifarmacorresistencia desarrollada por la bacteria, dicha resistencia es más frecuente en infecciones que requieren un tratamiento prolongado, lo cual conduce a mayor riesgo de incumplimiento por parte del paciente. Considerando la problemática asociada al tratamiento de la tuberculosis, el desarrollo de un sistema que libere isoniazida de manera sostenida representa una forma para mejorar el cumplimiento de la terapia, permitiendo mantener las concentraciones plasmáticas del fármaco en el rango terapéutico y reducir el riesgo de desarrollo de resistencia por el Mycobacterium tuberculosis. Contribuciones y Conclusiones: En el presente trabajo de investigación se evaluaron las características de liberación de la isoniazida incorporada en una matriz cerámica a base de SiO2 a condiciones fisiológicas in vitro. La síntesis del biomaterial se realizó vía sol-gel a diferentes condiciones de pH y relación TEOS/Agua. El material cerámico conteniendo la isoniazida fue caracterizado mediante técnicas térmicas, espectrométricas y microscópicas. Se realizaron pruebas de extracción para determinar la incorporación de isoniazida en el biomaterial, así como ensayos in vitro para evaluar las características de liberación de isoniazida en solución acuosa a pH fisiológico y mediante la determinación de permeabilidad en membranas artificiales. La cinética de liberación a pH fisiológico ocurrió en dos fases y esta dependió directamente de la morfología y de las propiedades texturales de la matriz, el factor más importante fue la porosidad, mientras que el estudio de permeabilidad de isoniazida en membranas artificiales indica que no se ve afectada cuando esta se incorporó en los biomateriales.

Design of functional hybrid coatings with anti-biofouling, self-cleaning and anti-reflecting applications

263 p.

Development of advanced catalytic systems for the selective hydrogenolysis of biomass-derived polyols

195 p.

Produção de fibras de alumina biomórfica a partir do sisal

Sisal is a renewable agricultural resource adapted to the hostile climatic and soil conditions particularly encountered in the semi-arid areas of the state of Rio Grande do Norte. Consequently, sisal has played a strategic role in the economy of the region, as one of few options of income available in the semi-arid. Find new options and adding value to products manufactured from sisal are goals that contribute not only to the scientific and technological development of the Northeastern region, but also to the increase of the family income for people that live in the semi-arid areas where sisal is grown. Lignocellulosic fibers are extracted from sisal and commonly used to produce both handcrafted and industrial goods including ropes, mats and carpets. Alternatively, addedvalue products can be made using sisal to produce alumina fibers (Al2O3) by biotemplating, which consists in the reproduction of the natural fiber-like structure of the starting material. The objective of this study was to evaluate the conditions necessary to convert sisal into alumina fibers by biotemplating. Alumina fibers were obtaining after pretreating sisal fibers and infiltrating them with a Al2Cl6 saturated solution, alumina sol from aluminum isopropoxide or aluminum gas. Heat-treating temperatures varied from 1200 ºC to 1650 °C. The resulting fibers were then characterized by X-ray diffraction and scanning electronic microscopy. Fibers obtained by liquid infiltration revealed conversion only of the surface of the fiber into α-Al2O3, which yielded limited resistance to handling. Gas infiltration resulted in stronger fibers with better reproduction of the inner structure of the original fiber. All converted fibers consisted of 100% α-Al2O3 suggesting a wide range of technological applications especially those that require thermal isolation

Improved Dynamic Headspace Sampling and Detection using Capillary Microextraction of Volatiles Coupled to Gas Chromatography Mass Spectrometry

Sampling and preconcentration techniques play a critical role in headspace analysis in analytical chemistry. My dissertation presents a novel sampling design, capillary microextraction of volatiles (CMV), that improves the preconcentration of volatiles and semivolatiles in a headspace with high throughput, near quantitative analysis, high recovery and unambiguous identification of compounds when coupled to mass spectrometry. The CMV devices use sol-gel polydimethylsiloxane (PDMS) coated microglass fibers as the sampling/preconcentration sorbent when these fibers are stacked into open-ended capillary tubes. The design allows for dynamic headspace sampling by connecting the device to a hand-held vacuum pump. The inexpensive device can be fitted into a thermal desorption probe for thermal desorption of the extracted volatile compounds into a gas chromatography-mass spectrometer (GC-MS). The performance of the CMV devices was compared with two other existing preconcentration techniques, solid phase microextraction (SPME) and planar solid phase microextraction (PSPME). Compared to SPME fibers, the CMV devices have an improved surface area and phase volume of 5000 times and 80 times, respectively. One (1) minute dynamic CMV air sampling resulted in similar performance as a 30 min static extraction using a SPME fiber. The PSPME devices have been fashioned to easily interface with ion mobility spectrometers (IMS) for explosives or drugs detection. The CMV devices are shown to offer dynamic sampling and can now be coupled to COTS GC-MS instruments. Several compound classes representing explosives have been analyzed with minimum breakthrough even after a 60 min. sampling time. The extracted volatile compounds were retained in the CMV devices when preserved in aluminum foils after sampling. Finally, the CMV sampling device were used for several different headspace profiling applications which involved sampling a shipping facility, six illicit drugs, seven military explosives and eighteen different bacteria strains. Successful detection of the target analytes at ng levels of the target signature volatile compounds in these applications suggests that the CMV devices can provide high throughput qualitative and quantitative analysis with high recovery and unambiguous identification of analytes.

Avenues de synthèse d’un matériau magnétique multifonctionnel à des fins de catalyse hétérogène

La catalyse est à la base de la fabrication de médicaments, de produits textiles, d‘engrais, des pots d’échappement, et une multitude d’autres applications de notre quotidien. En effet, dans les pays industrialisés jusqu’à 80% des produits manufacturés utilisés au quotidien ont nécessité au moins une étape de catalyse lors de leur fabrication. Outre être actif, il est primordial pour un catalyseur performant d’être résistant à la désactivation qui se traduit par la perte d’activité ou de sélectivité d’un catalyseur au cours du temps. La synthèse d’un matériau multifonctionnel permet de répondre à ces différents critères. L’objectif d’un design intelligent de matériaux est de mener à des effets synergiques de chacune des composantes. Pour un catalyseur, en plus d’être actif et sélectif pour le produit désiré, il faut en plus qu’il soit durable, stable dans le temps, et permette d’être réutilisable. L’objectif de ce projet est de faire une synthèse originale, simple et reproductible d’un catalyseur actif et résistant à la désactivation. De base, un catalyseur se compose d’un support et d’un matériau actif. La nature, la morphologie et l’agencement de ces derniers dictent le comportement chimique du catalyseur final. Comme matériau actif, les nanoparticules d’or sont très prisées en raison de leur potentiel de catalyse élevée pour de nombreuses réactions. Cependant, aux températures de fonctionnement de la catalyse, les nanoparticules d’or ont tendance à se désactiver par coalescence. Pour remédier à cela, il est possible de déposer une couche de silice mésoporeuse afin de protéger les NPs d’or des rudes conditions de réaction tout en étant perméables aux espèces réactives. Plusieurs types de matériaux peuvent servir de support aux nanoparticules d’or. À ce titre, les particules d’oxydes de fer magnétiques telles que la magnétite (Fe[indice inférieur 3]O[indice inférieur 4]) sont intéressantes pour leur potentiel hyperthermique, phénomène par lequel des nanoparticules (NPs) magnétiques transforment de l’énergie électromagnétique provenant d’un champ externe haute fréquence en chaleur, créant ainsi des nano-fours. Une première couche de silice est utilisée comme matrice de greffage afin de fixer les nanoparticules d’or sur la magnétite. La structure visée est illustrée à la Figure ci-dessous. Figure 1 Structure du catalyseur de Fe2O4@SiO2-Au-SiO2m (Ge, Zhang, Zhang, & Yin, 2008) Plusieurs avenues d’assemblage et de synthèse sont explorées pour chacune des composantes de la structure visée. Les avantages et inconvénients ainsi que des mécanismes sont proposés pour chaque voie de synthèse. Le matériau est utilisé comme catalyseur pour la réaction de réduction du 4-Nitrophénol par du NaBH4. Pour ce qui est de la synthèse de magnétite par voie solvothermique, il a été démontré qu’il était important d’être dans un milieu sous pression puisque l’étape limitante de la réaction est la solubilité des particules de magnétites dans le milieu. Cela est en accord avec le principe de mûrissement d’Ostwald selon lequel les petites particules ont tendance à se dissoudre dans le milieu et précipiter à la surface des plus grosses particules de façon à diminuer l’énergie interfaciale. Cette synthèse a été reproduite avec succès et a mené à la production de nanoparticules de Fe[indice inférieur 3]O[indice inférieur 4] sphériques creuses d’une taille de 150 [plus ou moins] 30nm. Ces sphères creuses ont été recouvertes d’une couche de silice dense par une méthode de Stöber modifiée. Le recouvrement forme des amas de particules et est non uniforme en raison de la présence de poly(éthlyène glycol) à la sur face de la magnétite, un adjuvant présent lors de sa synthèse afin d’améliorer la dispersion de la magnétite. La synthèse et le greffage d’AuNPs sont bien maîtrisés : les AuNPs ont une taille de 17 [plus ou moins] 6nm et la quantité d’or greffé est assez élevée. Ultimement, une méthode de greffage alternative tel que le greffage par croissance in situ de nanoparticules d’or pourrait être emprunté afin d’obtenir des particules plus petites. Pour ce qui est de la formation d’une couche de silice mésoporeuse, la méthode par calcination est une meilleure option que par gravure chimique en raison de sa sélectivité envers la couche externe de silice plus élevée ainsi que la formation apparente de pores.

Carbon aerogels used in carbon dioxide capture

In this work the maximum carbon dioxide adsorption capacity of carbon aerogels, obtained by a sol-gel process using 2,4-dihydroxybenzoic acid/formaldehyde (DHBAF) and resorcinol/formaldehyde (RF) as precursors, was studied. The effect of increasing the temperature of carbonization and physical activation of the samples DHBAF was also studied. The results showed that the maximum adsorption capacity is favoured at lower temperatures, adsorption and desorption are rapid and the performance is maintained over several cycles of CO2 adsorption/desorption. A comparison with samples of commercial carbons was also made and it was concluded that carbon aerogels exhibit a behaviour comparable or superior to that obtained for the commercial carbons studied.

Theoretical and experimental studies of gold catalysts for glucose oxidation

The glucaric acid (GLA) has been identified as a “top value-added chemical from biomass” that can be employed for many uses; for instance, it could be a precursor of adipic acid, a monomer of Nylon-6,6. GLA can be synthetized by the oxidation of glucose (GLU), passing through the intermediate gluconic acid (GLO). In recent years, a new process has been sought to obtain GLA in an economic and environmental sustainable way, in order to replace the current use of HNO3 as a stoichiometric oxidant, or electrocatalysis and biochemical synthesis, which show several disadvantages. Thereby, this work is focused on the study of catalysts based on gold nanoparticles supported on activated carbon for the oxidation reaction of GLU to GLA using O2 as an oxidant agent and NaOH as base. The sol-immobilization method leads us to obtain small and well dispersed nanoparticles, characterized by UV-Vis, XRD and TEM techniques. Repeating the reaction on different batches of catalyst, both the synthesis and the reaction were confirmed to be reproducible. The effect of the reaction time feeding GLO as reagent was studied: the results show that the conversion of GLO increases as the reaction time increases; however, the yields of GLA and others increase up to 1 hour, and then they remain constant. In order to obtain information on the catalytic mechanism at the atomistic level, a computational study based on density functional theory and atomistic modeling of the gold nano-catalyst were performed. Highly symmetric (icosahedral and cubo-octahedral) and distorted Au55 nanoparticles have been optimized along with Au(111) and Au(100) surfaces. Distorted structures were found to be more stable than symmetrical ones due to relativistic effects. On these various models the adsorptions of various species involved in the catalysis have been studied, including OH- species, GLU and GLO. The study carried out aims to provide a method for approaching to the study of nanoparticellary catalytic systems.

Nanostructured smart materials as functional components of medical devices

The field of medical devices has experienced, more than others, technological advances, developments and innovations, thanks to the rapidly expanding scientific knowledge and collaboration between different disciplines such as biology, engineering and materials science. The design of functional components can be achieved by exploiting composite materials based on nanostructured smart materials, that due to the inherent characteristics of single constituents develop unique properties that make them suitable for different applications preserving excellent mechanical proprieties. For instance, recent developments have focused on the fabrication of piezoelectric devices with multiple biomedical functions, as actuation and sensing functions in one component for monitoring pressure signals. The present Ph.D. Thesis aims at investigating nanostructured smart materials embedded into a polymeric matrix to obtain a composite material that can be used as a functional component for medical devices. (i) Nanostructured piezoelectric material with self-sensing capability was successfully manufactured by using ceramic (i.e. lead zirconate titanate (PZT)) and (ii) polymeric (i.e. poly(vinylidene fluoride-trifluoro ethylene (PVDF-TRFE)) piezoelectric materials. PZT nanofibers were obtained by sol-gel electrospinning starting from synthetized PZT precursor solution. Synthesis, sol-gel electrospinning process, and thermal treatment were accurately controlled to obtain PZT nanofibers dimensionally stable with densely packed grains in the perovskite phase. To guarantee the impact resistance of the laminate, the morphology and size of the hosting filler were accurately designed by increasing the surface area to volume ratio. Moreover, to solve the issue relative to the mechanical discrepancy between rigid electronic materials/soft human tissues/different material of the device (iii) a nanostructured flexible composite material based on a network of Poly-L-lactic acid (PLLA) made of curled nanofibers that present a tuneable mechanical response as a function of the applied stress was successful fabricated.

Sviluppo ed ingegnerizzazione di nuovi sistemi ibridi a base di nanoparticelle inorganiche e bio-tensioattivi

In questo lavoro di tesi è stata investigata la sintesi di compositi a base di nano particelle di biossido di titanio rivestite da un bio-tensioattivo naturale. Il noto fotocatalizzatore (Nano-TiO2) è stato accoppiato ad un bio-tensioattivo dalle riconosciute proprietà antibatteriche, antivirali e anti-tumorali per ottenere un materiale composito multifunzionale. Diverse opzioni di design sono state investigate e la sintesi ottimizzata attraverso una caratterizzazione sistematica dei materiali prodotti, sia sulle sospensioni (DLS, ELS, TEM) sia sui prodotti granulati e calcinati (XRD, FT-IR, SEM, UV-Vis., BET). Per comprendere il ruolo del bio-tensioattivo e i potenziali effetti sinergici che il materiale composito potesse generare, si sono effettuate diverse caratterizzazioni funzionali testando il materiale per la realizzazione di nano-fasi fotocatalitiche da impiegare in processi di adsorbimento/degradazione di inquinanti acquosi, per la realizzazione di rivestimenti tessili antibatterici e come composito utile per l’assorbimento di metalli pesanti.